A method and apparatus for printing a desired pattern on a substrate by discharging continuous streams of liquid ink drops from nozzles towards the substrate, and selectively charging the liquid ink drops with multi-level charges deflecting them different amounts. Some of the liquid ink drops are thus directed to different locations on the substrate for printing the desired pattern thereon, while other liquid ink drops not to be printed are intercepted by a gutter before reaching the substrate. At least some of the liquid ink drops to be printed being either uncharged or charged with a multi-level charge of one polarity, while all the liquid ink drops not to be printed are charged with a charge of the opposite polarity. Each stream of ink drops discharged from a nozzle is illuminated with stroboscopic light at the same frequency as the drop formation, and the illuminated stream is optically sensed on the fly for determining various conditions, including ink velocity, X-axis offset and Y-axis offset.
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1. A method of printing a desired pattern on a substrate, comprising:
discharging a continuous stream of liquid ink drops from a nozzle along the nozzle axis towards the substrate;
selectively charging said liquid ink drops with multilevel charges for selectively deflecting them different amounts with respect to the nozzle axis to thereby direct some of the liquid ink drops to different locations on the substrate for printing said desired pattern thereon, while other liquid ink drops not to be printed are intercepted by a gutter before reaching the substrate;
illuminating the stream of liquid ink drops discharged from the nozzle with stroboscopic light at the frequency of the drop formation;
optically sensing and displaying an image of the illuminated stream of liquid drops and the distance between the first and last drops;
and calculating the velocity of the liquid drops according to the image displayed.
9. A method of printing a desired pattern on a substrate, comprising:
discharging a continuous stream of liquid ink drops from a nozzle along the nozzle axis towards the substrate;
and selectively charging said liquid ink drops with multilevel charges for selectively deflecting them different amounts with respect to the nozzle axis to thereby direct some of the liquid ink drops to different locations on the substrate for printing said desired pattern thereon, while other liquid ink drops not to be printed are intercepted by a gutter before reaching the substrate;
wherein the stream of ink drops produced from the nozzle is divided into two streams by charging pulses of two charging levels and of appropriate phases; and wherein the two streams of ink drops are optically sensed by an imaging system for determining, and for correcting; velocity errors, and/or charge phasing errors between the respective charging pulses and the physical drop formation timing in the stream exiting from the nozzle.
14. A method of printing a desired pattern on a substrate, comprising:
discharging a plurality of continuous streams of liquid ink drops from a plurality of nozzles having nozzle axes arranged in at least one row;
selectively charging said liquid ink drops by input data, according to the pattern desired to be printed, with multilevel charges for selectively deflecting said liquid ink drops given amounts with respect to their respective nozzle axes to thereby direct some of the liquid ink drops to different locations on the substrate for printing said desired pattern thereon, while other liquid ink drops not to be printed are intercepted by a gutter before reaching the substrate;
utilizing at least two sensor devices for sensing the liquid ink drops of each of said streams, said sensor devices having sensor axes at a predetermined angle to each other;
and processing outputs of said sensor devices, including said predetermined angle of their sensor axes, to compute deviations of the respective stream of ink drops from the respective nozzle axis (a) in the direction parallel to said row of nozzles (X-axis offset), and (b) in the direction perpendicular to said row of nozzles (Y-axis offset).
13. A method of printing a desired pattern on a substrate, comprising:
forming a continuous stream of liquid ink drops by an acoustical excitation device in a nozzle;
discharging the stream of drops from nozzle along the nozzle axis towards the substrate;
and selectively charging said liquid ink drops with multi-level charges for selectively deflecting them different amounts with respect to the nozzle axis to thereby direct some of the liquid ink drops to different locations on the substrate for printing said desired pattern thereon, while other liquid ink drops not to be printed are intercepted by a gutter before reaching the substrate;
wherein the forming of the liquid ink drops is monitored on the fly by illuminating the stream of drops with stroboscopic light at the frequency of the drop formation, an image of a plurality of liquid drops in the illuminated streams is optically sensed and displayed; the distance between the first and last drops in the displayed image is observed to determine the velocity of the individual drops in a manner which tends to cancel noise and drop break-off is controlled by controlling said acoustical excitation device to avoid satellite formations in the displayed image of drops.
19. printing apparatus for printing a desired pattern on a substrate, comprising:
a plurality of nozzles for forming and discharging continuous streams of liquid ink drops along the respective nozzle axis towards the substrate, said nozzles being arranged in at least one row;
charging plates for each nozzle for selectively charging the liquid ink drops of the respective nozzle with input data according to the pattern desired to be printed;
deflecting plates for each nozzle for selectively deflecting the liquid ink drops different amounts with respect to the respective nozzle axis for printing on a substrate the desired pattern;
a gutter for intercepting, before reaching the substrate, the liquid ink drops not to be printed;
at least two sensor devices for sensing the liquid ink drops in each of said continuous streams, said sensor devices having sensor axes at a predetermined angle to each other; and
a control system for controlling said charging plates and said deflecting plates, said control system processing outputs from said sensor devices, computing deviations of the respective stream of ink drops from the respective nozzle axis (a) in the direction parallel to said row of nozzles (X-axis offset), and (b) in the direction perpendicular to said row of nozzles (Y-axis offset); and correcting the pattern printed by the respective nozzle in accordance with the computed deviations.
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This Application is a U.S. Divisional Application of U.S. patent application Ser. No. 10/475,523, filed on Oct. 29, 2003, which is a U.S. National Phase of PCT Application No. PCT/IL02/00346, filed on May 2, 2002, which claims the benefit of U.S. Provisional Patent Application No. 60/288,097, filed on May 3, 2001. The contents of the above Applications are incorporated herein by reference.
The present invention relates to ink jet printers and methods of printing by ink jets. The present invention is particularly useful in the apparatus and methods described in our prior U.S. Pat. Nos. 5,969,733, 6,003,980 and 6,106,107, the contents of which are hereby incorporated by reference. The invention is therefore described below with regard to such apparatus and methods, but it will be appreciated that the invention could also be used in other apparatus and methods.
Ink jet printers are based on forming drops of liquid ink and selectively depositing the ink drops on a substrate. The known ink jet printers generally fall into two categories: drop-on-demand printers, and continuous-jet printers.
Drop-on-demand printers selectively form and deposit the ink jet drops on the substrate as and when demanded by a control signal from an external data source. Such systems typically use nozzles having relatively large openings, ranging from 30 to 100 μm.
Continuous-jet printers, on the other hand, are stimulated by a perturbation device, such as a piezoelectric transducer, to form the ink drops from a continuous ink jet filament at a rate determined by the perturbation device. The drops are selectively charged and deflected to direct them onto the substrate according to the desired pattern to be printed.
Continuous-jet printers are divided into two types of systems: binary, and multi-level. In binary systems, the drops are either charged or uncharged and, accordingly, either reach or do not reach the substrate at a single predetermined position. In multi-level systems, the drops can receive a large number of charge levels and, accordingly, can generate a large number of print positions.
The process of drop formation depends on many factors associated with the ink rhelogy (e.g. viscosity, surface tension), the ink flow conditions (e.g. jet diameter, jet velocity), and the characteristics of the perturbation (e.g. frequency and amplitude of the excitation). Typically, drop formation is a fast process, occurring in the time frame of a few microseconds. However, because of possible variations in one or more of the several factors determining the drop formations, variations are possible in the exact timing of the drop break-off. These timing variations can cause incorrect charging of drops if the electrical field responsible for drop charging is turned-on, turned-off, or changed to a new level, during the drop break-off itself. Therefore it is necessary to keep the data pulse precisely in-phase relative to the drop break-off timing, in order to obtain accurate drop charging and printing.
Another type of commonly-occurring printing error is incorrect velocity of the ink drops such that the ink drop is not deflected to its proper position on the substrate. Drop velocity (or jet speed) errors may be produced by many different factors, such as those associated with the ink rhelogy and/or the ink flow conditions. Such errors may be corrected by changing the drop charging voltage applied to the ink drops since the amount of deflection experienced by the ink drops before impinging the substrate depends on the drop velocity, the voltage applied to the deflector plates electric field, and the drop charge.
A still further problem in ink jet printing is the formation of satellites in the stream of drops. Satellites are characterized by volumes which are much smaller (typically by more than one order of magnitude) than the basic drop volume, i.e. the volume within the drop desired to be printed. In the usual capacitively charged configurations, satellites carry a charge similar to the charge carried by the basic drop. The acceleration experienced by charged drops in an electrical field is inversely proportional to their masses. Since the mass of the satellite is much smaller than the mass of the basic drop, satellites will experience a much stronger acceleration inside the deflection field, and may therefore impinge against the deflecting plates. This could result in an electrical breakdown condition or other malfunction of the printer.
The above-cited U.S. Pat. No. 6,003,980 discloses a method and apparatus for sensing improper operation of an ink jet printer by printing test marks on a test strip, and then analyzing the printed test marks. However, such a technique is not always practical or convenient particularly with respect to ink jet printers including a large number of nozzles. In addition, relying on an analysis of printed marks on a substrate for sensing improper operation of an ink jet printer may suffer from lack of consistency because of inconsistencies in the substrates themselves.
An object of the present invention is to provide a method of ink jet printing, and also an ink jet printing apparatus, having advantages in one or more of the above respects.
According to one aspect of the present invention, there is provided a method of printing a desired pattern on a substrate, comprising: discharging a continuous stream of liquid ink drops from a nozzle along the nozzle axis towards the substrate; selectively charging the liquid ink drops with multi-level charges for selectively deflecting them different amounts with respect to the nozzle axis to thereby direct some of the liquid ink drops to different locations on the substrate for printing the desired pattern thereon, while other liquid ink drops not to be printed are intercepted by a gutter before reaching the substrate; at least some of the liquid ink drops to be printed being either uncharged or charged with a multi-level charge of one polarity, while all the liquid ink drops not to be printed are charged with a charge of the opposite polarity; illuminating the stream of liquid ink drops discharged from the nozzle with stroboscopic light at the frequency of the drop formation; optically sensing and displaying an image of the illuminated stream of liquid drops and the distance between the first and last drops in the image; and calculating the velocity of the liquid drops according to the image displayed.
As will be described more particularly below, such a feature enables the uncharged (free-fall) drops to be used for printing and also for calibration purposes as will be described more particularly below. Another advantage of this feature is that it enables a relatively wide drop “fan” to be created without increasing the charges on the drops having the longest deflection since the relatively low charged drops are printing drops, and not non-printing drops to be directed to the gutter.
In one described preferred embodiment, each of the liquid ink drops to be printed is either uncharged or charged with a multi-level charge of the one polarity; and in a second described embodiment, each of the liquid ink drops to be printed is also charged with a multi-level charge of the opposite polarity but of a lower level than that of the liquid ink drops not to be printed.
According to a further embodiment, the liquid ink drops are selectively deflected by deflecting plates which diverge in the direction towards the substrate. This feature also enables the “fan” to be increased, without increasing the voltage level of the charges to be applied to the drops.
According to another aspect of the invention, there is provided a method of printing a desired pattern on a substrate, comprising: discharging a continuous stream of liquid ink drops from a nozzle along the nozzle axis towards the substrate; and selectively charging the liquid ink drops with multi-level charges for selectively deflecting them different amounts with respect to the nozzle axis to thereby direct some of the liquid ink drops to different locations on the substrate for printing the desired pattern thereon, while other liquid ink drops not to be printed are intercepted by a gutter before reaching the substrate; the stream of liquid ink drops discharged from the nozzle being illuminated with stroboscopic light at the frequency of the drop formation; and the illuminated stream of liquid ink drops being optically sensed on the fly for determining the ink velocity of the stream of drops.
According to further features in the described preferred embodiments, the illuminated stream of drops is sensed by a camera having an imaging lens. Errors in the ink velocity may be determined by comparing the optically-sensed stream of drops with a reference and may be compensated for by modifying the charges applied to the drops.
According to a still further aspect of the present invention, there is provided a method of printing a desired pattern on a substrate, comprising: discharging a continuous stream of liquid ink drops from a nozzle along the nozzle axis towards the substrate; and selectively charging the liquid ink drops with multi-level charges for selectively deflecting them different amounts with respect to the nozzle axis to thereby direct some of the liquid ink drops to different locations on the substrate for printing the desired pattern thereon, while other liquid ink drops not to be printed are intercepted by a gutter before reaching the substrate; wherein two streams of ink drops are produced from the nozzle by charging pulses of two charging levels, the two streams of ink drops being illuminated by stroboscopic light at the frequency of the drop formation and being optically sensed on the fly by an imaging system for determining charge phasing errors between the respective charging pulses and the physical drop formation timing in the stream exiting from the nozzle.
According to a still further aspect of the invention, there is provided a method of printing a desired pattern on a substrate, comprising: forming a continuous stream of liquid ink drops by an acoustical excitation device in a nozzle; discharging the stream of drops from the nozzle along the nozzle axis towards the substrate; and selectively charging the liquid ink drops with multi-level charges for selectively deflecting them different amounts with respect to the nozzle axis to thereby direct some of the liquid ink drops to different locations on the substrate for printing the desired pattern thereon, while other liquid ink drops not to be printed are intercepted by a gutter before reaching the substrate; wherein the forming of the liquid ink drops is monitored on the fly by illuminating the stream of drops with stroboscopic light at the frequency of the drop formation, an image of a plurality of liquid drops in the illuminated streams is optically sensed and displayed; the distance between the first and last drops in the displayed image is observed to determine the velocity of the individual drops in a manner which tends to cancel noise and drop break-off is controlled by controlling the acoustical excitation device to avoid satellite formations in the displayed image of drops.
According to a still further aspect of the invention, there is provided a method of printing a desired pattern on a substrate, comprising: discharging a plurality of continuous streams of liquid ink drops from a plurality of nozzles having nozzle axes in linear alignment along a printing axis; selectively charging the liquid ink drops by input data, according to the pattern desired to be printed, with multi-level charges for selectively deflecting the liquid ink drops given amounts with respect to their respective nozzle axes to thereby direct some of the liquid ink drops to different locations on the substrate for printing the desired pattern thereon, while other liquid ink drops not to be printed are intercepted by a gutter before reaching the substrate; utilizing at least two sensor devices for sensing the liquid ink drops of each of the streams, the sensor devices having sensor axes at a predetermined angle to each other; and processing outputs of the sensor devices, including the predetermined angle of their sensor axes, to compute deviations of the respective stream of ink drops from the respective nozzle axis (a) in the direction perpendicular to the printing axis (X-axis offset), and (b) in the direction along the printing axis (Y-axis offset).
According to further features in the described preferred embodiment, the sensor devices are optical sensors, preferably cameras having an imaging lens and the streams of ink drops are illuminated with stroboscopic light at the same frequency as the drop formation.
According to further features in the described preferred embodiments, the computed X-axis offset for a particular nozzle is corrected by adjusting the charging voltages for the respective nozzle; and the computed Y-axis offset for a particular nozzle is corrected by adjusting the timing of the input data to the respective nozzle.
According to a further aspect of the invention, there is provided printing apparatus for printing a desired pattern on a substrate, comprising: a nozzle for forming and discharging a continuous stream of liquid ink drops along the nozzle axis towards the substrate; charging plates for selectively charging the liquid ink drops with multi-level charges; deflecting plates for selectively deflecting the liquid ink drops in different amounts with respect to the nozzle axis to thereby direct some of the liquid ink drops to different locations on the substrate for printing thereon the desired pattern; a gutter for intercepting, before reaching the substrate, the liquid ink drops not to be printed; and a control system for controlling the charging plates and the deflecting plates; the control system controlling the charging plates such that at least some of the liquid ink drops to be printed are either uncharged or charged with a multi-level charge of one polarity, while all the liquid ink drops not to be printed are charged with a charge of the opposite polarity.
According to a still further aspect of the invention, there is provided printing apparatus for printing a desired pattern on a substrate, comprising: a plurality of nozzles for forming and discharging continuous streams of liquid ink drops along the respective nozzle axis towards the substrate, the nozzles having nozzle axes in linear alignment along a printing axis; charging plates for each nozzle for selectively charging the liquid ink drops of the respective nozzle with input data according to the pattern desired to be printed; deflecting plates for each nozzle for selectively deflecting the liquid ink drops different amounts with respect to the respective nozzle axis for printing on a substrate the desired pattern; a gutter for intercepting, before reaching the substrate, the liquid ink drops not to be printed; at least two sensor devices for sensing the liquid ink drops in each of the continuous streams, the sensor devices having sensor axes at a predetermined angle to each other; and a control system for controlling the charging plates and the deflecting plates, the control system processing outputs from the sensor devices; computing deviations of the respective stream of ink drops from the respective nozzle axis (a) in the direction perpendicular to the printing axis (X-axis offset), and (b) in the direction along the printing axis (Y-axis offset); and correcting the pattern printed by the respective nozzle in accordance with the computed deviations.
Further features and advantages of the invention will be apparent from the description below.
The invention is herein described, by way of example only, with reference to the accompanied drawings, wherein:
It is to be understood that the foregoing drawings, and the description below, are provided primarily for purposes of facilitating understanding the conceptual aspects of the invention and various possible embodiments thereof, including what is presently considered to be a preferred embodiment. In the interest of clarity and brevity, no attempt was made to provide more details than necessary to enable one skilled in the art, using routine skill and design, to understand and practice the described invention. It is to be further understood that the embodiments described are for purposes of example only, and that the invention is capable of being embodied in other forms and applications than described herein.
The arrangement illustrated in
Further details of the construction and operation of such known ink jet printers as illustrated in
In the arrangement illustrated in
The arrangement illustrated in
A further important advantage is that the arrangement illustrated in
Thus, in the example illustrated in
The arrangement illustrated in
As indicated earlier, an important advantage in the arrangements illustrated in
The calibration technique illustrated in
V=H/(N−1) (SF)
wherein: V is the velocity of the free-fall stream of drops 5a; N is the number of drops displayed; H is the distance between the first and last drops (calibrated by reference to an external element or derived from reference elements in the image); and SF is the strobe frequency of operation of the illumination unit 10.
An image of a bi-level stream of charged drops having pre-determined charging drive values may be captured. This may be done by dividing the stream of ink drops from the nozzle into two streams by using charging pulses of two charging levels and appropriately phasing the timing of the charging pulses.
As indicated earlier, printing inaccuracies resulting from velocity errors produced by many different factors may be corrected by changing the charging voltages applied to the ink drops since the amount of deflection to be experienced by the drops before reaching the substrate depends both on the ink jet speed and the charging voltage applied to the charging plates.
As also indicated earlier, for accurate printing it is necessary that the charging pulses be applied to the charging plates 6 at the right phase relative to the drop break-off time, i.e., that the charging pulses be in an in-phase condition with respect to the drop break-off time. The stroboscopic arrangement illustrated in
For this purpose, a bi-level stream of charged drops is generated as illustrated in
Typically, at lower excitations, the drops before break-up are joined by filaments of decreasing thickness in the downstream direction. Upon increasing the excitation, there is a tendency to produce satellites; and upon further increasing the excitation, a condition is reached in which the filament joining two successive drops before break-up breaks from the rear drop and merges with the forward drop forming a forward tail. A further increase in excitation may lead, in certain cases, to a non-uniform behavior of the drop formation, including the return to the unwanted conditions of satellite formation or rear-merging formations.
By thus monitoring, by visually observing, the drop formations in a real-time manner as the amplitudes of the acoustic excitations are varied, it is possible to calibrate the apparatus so as to completely eliminate or minimize the formation of satellites.
As shown in
As described earlier, an important condition for proper operation of the printer is the speed of the free-fall stream of ink drops, which can be observed and the velocity computed in real-time. The computation of the ink drop velocity may be done manually, e.g. by comparison with reference tables or diagrams, or can be computed automatically.
As further indicated above, printing errors resulting from variations in the drop formation within the acceptable forward tail condition, and drop velocity, can be corrected by adjusting the charging voltages applied to the charging plates 23 since the amount of deflection experienced by the ink drops depends not only on the drop velocity, but also on the voltage on the plates which determine the charging of the drops. Thus, the system controller 25 could include a manual (or automatic) input device 45 for controlling the charger circuit 27 to compensate for drop velocity errors or incorrect drop charging.
Printing errors resulting from incorrect phasing between the charging pulses applied to the ink drops at the nozzles 21 and the ink drop break-off times, can be corrected by an input 46 to the system controller 25 controlling the phase shifter circuit 28.
The formation of satellites in the ink drops can be suppressed by an input 47 to the system controller 25 for controlling the piezoelectric perturbation drive 31. As described above, the perturbation device within the printer head 20 can be controlled so as to produce an optimum shape of the ink drops and with no, or substantially no, satellites.
In all other respects, the apparatus illustrated in
As indicated in
During calibration, several frames are captured by imaging devices 61 and 62 at successive jet positions (xi, yi). These frames are digitized through a frame grabber. From the values of (Si1x, Si1y) and (Si2x, Si2y), the values of x offset and y offset for each jet can be derived.
The object is to measure the geometrical position of the streams of jets with high accuracy by using a stroboscopic arrangement of imaging devices.
In
Dx=the separation in the x axis between the center of imaging device 61 and the center of imaging device 62;
Dy=the separation in the y axis between the center of imaging device 61 and the center of imaging device 62;
α=the angle between imaging device 61 and imaging device 62;
f1=the focal length of the imaging device 61;
f2=the focal length of imaging device 62;
c1=the center of the image plane on the CCD in imaging device 61;
c2=the center of the image plane on the CCD in imaging device 62.
The method employs multiple measurement of each jet, while each measurement is performed at a slightly different position of the cameras carriage relative to the line of jets. The movement of the carriage is accurately measured by an encoder. The movement of the carriage is adjusted to be predominantly parallel to the row of nozzles (or in an alternative language—to the plane defined by the jets).
For each measurement position, a certain number of jets are measured (for instance three jets) simultaneously by the two cameras 41, 50. According to the laws of geometrical optics, a set of equations will be derived for each camera for each measurement position. Therefore, if “n” measurements are performed, a set of 2n equations will be obtained which have the general form:
ynA1=xnB1+C1
ynA2=xnB2+C2
Where A1,2, B1,2 and C1,2 represent equations between the geometrical parameters and the measured quantities (x,S1x,S1y,S2x,S2y).
The solution for this set of equations, for each value of n, is:
Xn=(C2A1−C1A2)/B1A2−B2A1)
Yn=(XnB2+C2)/A2
A numerical solution is possible for the above equations once the values of the geometrical parameters are known. In the method employed, a solution was found which overcomes the necessity to measure the geometrical parameters, but rather computes them from the set of equations and measurements by employing the following steps:
i) a set of initial parameters is defined;
ii) using this initial set of parameters, the positions of each jet is computed. For each jet there will be several solutions since each jet is measured several times at different cameras positions (according to the movement of the carriage);
iii) the quadratic position error for each jet is computed from the solutions in ii) above;
iv) the initial geometrical parameters are changed until the minimum quadratic errors for all jets are obtained. This optimization process is performed in successive steps where initially only a reduced number of geometrical parameters is varied—for instance, if four parameters out of the seven possible parameters are varied there will be 37 different sets of parameters. Subsequently, only a limited number of the possible different sets will be chosen which give the minimum error (for instance 10 sets); and around this reduced group of preferred sets slightly different sets will be analyzed;
v) the final result of the algorithm and computation method provides the optimal set of geometrical parameters to be used for computing the positions of the jets and from the measurements performed, provides the x and y position for each jet.
While the invention has been described with respect to several preferred embodiments, it will be appreciated that these are set forth merely for purposes of example, and that many other variations, modifications and applications of the invention may be made.
Sheinman, Yehoshua, Ben-Shahar, Ilan, Weksler, Meir
Patent | Priority | Assignee | Title |
11220104, | Dec 22 2017 | Hewlett-Packard Development Company, L.P. | Reducing inkjet aerosol |
8454134, | Jan 26 2012 | Eastman Kodak Company | Printed drop density reconfiguration |
8540351, | Mar 05 2012 | Milliken & Company | Deflection plate for liquid jet printer |
8714674, | Jan 26 2012 | Eastman Kodak Company | Control element for printed drop density reconfiguration |
8714675, | Jan 26 2012 | Eastman Kodak Company | Control element for printed drop density reconfiguration |
8752924, | Jan 26 2012 | Eastman Kodak Company | Control element for printed drop density reconfiguration |
8764168, | Jan 26 2012 | Eastman Kodak Company | Printed drop density reconfiguration |
8807715, | Jan 26 2012 | Eastman Kodak Company | Printed drop density reconfiguration |
9452602, | May 25 2012 | Milliken & Company | Resistor protected deflection plates for liquid jet printer |
9550355, | Jan 21 2016 | Milliken & Company | Resistor protected deflection plates for liquid jet printer |
Patent | Priority | Assignee | Title |
4148718, | Jun 10 1976 | Coulter Electronics, Inc. | Single drop separator |
4350986, | Sep 11 1976 | Hitachi, LTD | Ink jet printer |
4491852, | Jul 02 1982 | Ricoh Company, Ltd. | Ink jet printing apparatus using guard drops |
4688049, | Jun 11 1985 | Domino Printing Sciences Plc | Continuous ink jet printing |
5410342, | Jan 24 1990 | Domino Printing Sciences Plc of Bar Hill | Printhead for continuous ink jet printer |
5455614, | Sep 06 1991 | Linx Printing Technologies PLC | Printing method and print head having angled ink jet |
5821963, | Sep 16 1994 | Marconi Data Systems Inc | Continuous ink jet printing system for use with hot-melt inks |
5975682, | Aug 07 1996 | BOARD OF TRUSTEES OF THE LELAND STANFORD JUNIOR UNIVERSITY, THE | Two-dimensional fluid droplet arrays generated using a single nozzle |
5988480, | Dec 12 1997 | Micron Technology, Inc. | Continuous mode solder jet apparatus |
6003980, | Mar 28 1997 | Jemtex Ink Jet Printing Ltd. | Continuous ink jet printing apparatus and method including self-testing for printing errors |
6224180, | Feb 21 1997 | KPS SPECIAL SITUATIONS FUND II L P | High speed jet soldering system |
20040130585, | |||
GB1124163, | |||
WO2090119, |
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